Enhancing a Molecular Electrocatalyst’s Activity for CO2 Reduction by Simultaneously Modulating Three Substituent Effects

IF 3.784 3区 化学 Q1 Chemistry ACS Combinatorial Science Pub Date : 2021-03-08 DOI:10.1021/jacs.0c09357
Weixuan Nie, Drew E. Tarnopol, Charles C. L. McCrory*
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引用次数: 32

Abstract

The electrocatalytic activity for CO2 reduction is greatly enhanced for Co complexes with pyridyldiimine-based ligands through the stepwise integration of three synergistic substituent effects: extended conjugation, electron-withdrawing ability, and intramolecular electrostatic effects. The stepwise incorporation of these effects into the catalyst structures results in a series of complexes that show an atypical inverse scaling relationship for CO2 reduction—the maximum activity of the resulting catalysts increases as the onset potentials are driven positive due to the ligand electronic substituent effects. Incorporating all three effects simultaneously into the catalyst structure results in a Co complex [Co(PDI-PyCH3+I)] with dramatically enhanced activity for CO2 reduction, operating with over an order of magnitude higher activity (TOFcat = 4.1 × 104 s–1) and ~0.2 V more positive catalytic onset (Eonset = ?1.52 V vs Fc+/0) compared to the parent complex, an intrinsic activity parameter TOF0 = 6.3 × 10–3 s–1, and >95% Faradaic efficiency for CO production in acetonitrile with 11 M water. This makes [Co(PDI-PyCH3+I)] among the most active molecular catalysts reported for the CO2 reduction reaction. Our work highlights a promising catalyst design strategy for molecular CO2RR catalysts in which catalytic ability is enhanced by tuning three synergistic substituent effects simultaneously in a single catalyst structure.

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通过同时调节三个取代基效应提高分子电催化剂的CO2还原活性
以吡啶基二亚胺为配体的Co配合物通过扩展共轭、吸电子能力和分子内静电效应三种协同取代基效应的逐步整合,大大增强了Co配合物还原CO2的电催化活性。将这些效应逐步纳入催化剂结构中会产生一系列配合物,这些配合物在CO2还原中表现出非典型的逆标关系——随着配体电子取代基效应导致起始电位为正,所得到的催化剂的最大活性增加。将所有三个效应同时纳入催化剂结构导致公司复杂[有限公司(PDI-PyCH3 + I)]大大增强活动减少二氧化碳操作超过一个数量级高活动(TOFcat = 4.1×104 s - 1)和V ~ 0.2更积极的催化发作(Eonset = ? 1.52 V和Fc + / 0)到父复杂相比,一个内在活性参数TOF0 = 6.3×三s - 1,并在公司生产的感应电流的效率达到95%乙腈与11米水。这使得[Co(PDI-PyCH3+I -)]成为报道的CO2还原反应中最活跃的分子催化剂之一。我们的工作强调了一种有前途的分子CO2RR催化剂设计策略,其中通过在单个催化剂结构中同时调节三个协同取代基效应来增强催化能力。
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ACS Combinatorial Science
ACS Combinatorial Science CHEMISTRY, APPLIED-CHEMISTRY, MEDICINAL
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审稿时长
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期刊介绍: The Journal of Combinatorial Chemistry has been relaunched as ACS Combinatorial Science under the leadership of new Editor-in-Chief M.G. Finn of The Scripps Research Institute. The journal features an expanded scope and will build upon the legacy of the Journal of Combinatorial Chemistry, a highly cited leader in the field.
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